JP5902850B1 - Tape transfer jig - Google Patents

Abstract

[PROBLEMS] To effectively use a simple method and a tool that is commonly used by an equipment business operator, such as an electric drill, so that it takes time for the tape to be transferred by a worker, In addition, the work burden can be reduced. A tape transfer jig 1 is a tape transfer jig 1 comprising a transmission member 2 for transmitting a rotational force from an electric driver 13 and a winding member 3 for winding the tape via the transmission member. The winding member is attached to the transmission member via the winding member holding projection 4 provided on the transmission member, and is fixed to the electric driver via the chucking portion 7 provided on the transmission member. Winding around the winding member. [Selection] Figure 2

Description

The present invention relates to a tape transfer jig for subdividing a tape, more specifically,
In installation work and maintenance work for facilities that employ a configuration in which multiple pipes are connected in a narrow area, the tape can be easily and quickly transferred to a shaft core with a small outer diameter, and the tape or the like can be wound. The invention relates to a tape transfer jig for subdivision that can improve the efficiency of facility construction work for heat insulation and waterproofing, and reduce work time and work load.

In building construction work and maintenance work, boiler facilities and hot water supply facilities are often installed in narrow places or high places, and workability is often poor. In addition, the facilities themselves have been reduced in size and weight in order to reduce the occupied space, and piping and wiring are inevitably reduced in distance and distance to the wall side. Therefore, the work space is narrow. These compactifications have many advantages, but have an aspect that increases the difficulty of work for the installer.
If there is a large gap between the pipes as in the previous equipment, the work of winding vinyl tape or the like around these pipes was easy. However, recent boilers, hot water supply facilities, and the like have become more compact, and as a result, various pipes are more closely arranged and the winding operation is more difficult. Therefore, in such a work site, there is a current situation in which an operator responds by rewinding the tape itself small.

Moreover, the diameter of a commercially available transmission member such as a vinyl tape is large, and there is a limit in reducing the diameter even if the amount of winding of the tape is reduced. Therefore, there is a need for a technique that can easily and quickly transfer only a necessary amount to a thinner core, and can eliminate waste even in the work burden and the time labor burden. The term “equipment construction” used in this document is not limited to the air conditioning facilities and equipment shown as examples, but refers to pipe construction in a broad sense, for the purposes of insulation, waterproofing, water leakage, corrosion prevention, heat insulation, etc. In addition, it includes facilities related to communication facilities, electrical work, telephone work, civil engineering, sanitary facilities, air conditioning facilities, and the like.

The above-mentioned work for subdividing the tape was a small work because the tape was wound up by its own work, and if the winding was bad, the tapes were glued together, and there were many types and widths. For example, it can be said that it is wasteful in creation time to divide the necessary number into small parts, which is a problem in terms of work efficiency.
Tape take-up machines are also commercially available, but they are relatively large devices that are difficult to use because they require more equipment to bring to the work site.
Therefore, there is a current situation that there is a need for a tape transfer jig that can be easily subdivided into a tape by being added to a tool used at a work site.

In addition, a jig (see Patent Document 1) that increases work efficiency by being added to an electric screwdriver has been proposed and is a known technique. More specifically, a bit 10A that engages the head of the screw and restricts its rotation is formed at the tip of the driver shaft, and the bit of the driver shaft is inserted into the cylindrical holder from the rear end. A plurality of retaining protrusions 12A for elastically retaining the head of the inserted screw extends toward the center, and the retaining head is elastically deformed by pulling the driver shaft rearward while the head of the screw is bit. It is possible to leave. A retaining cap 14 is fitted to the rear end of the cylindrical holder, the driver shaft projects from the central opening, the driver shaft is prevented from coming back, and the guide tube 11 is fitted to the outer periphery of the bit of the driver shaft. A spring member is externally mounted to bias the driver shaft rearward.

Such a technique is a structure to be added to a tool, but is a structure in which a screw is screwed stably. There is no description of subdividing a tape, and the above problem has not been solved.
In order to solve these problems, the present inventor pays attention to a jig as an attachment of an electric driver and leads to a proposal of a “tape transfer jig”.

Utility model registration 3190814

The present invention uses a simple method and a tool known as an electric drill, which is a tool that workers are familiar with, so that it takes time for the tape to be transferred by the operator. In addition, a new technical proposal that can reduce the work burden is an issue.

Invention tape wound transferred jig 1 according to the comprises a winding member for transferring up the tape via the transmission member and said transmission member for transmitting a rotational force from the electric driver consists, the transmission member is wound member holding And a winding member positioning portion and a chucking portion for obtaining a rotational force from the electric driver, and the winding member has a through hole into which the transmission member is inserted , The winding member is fitted to the winding member holding projection, and the rotational force from the electric driver is transmitted to the winding member via the chucking portion, and the tape is wound around the winding member. Thus, the tape is transferred from a large-diameter winding member to a small-diameter winding member .

  In addition, the present invention may employ a configuration in which the winding member holding protrusion is helical.

  In addition, the present invention may employ a configuration in which the winding member holding projections have a projection shape extending in the longitudinal direction.

  In addition, the present invention may employ a configuration in which the winding member positioning portion is any one of a step shape, a protruding shape, or a flange shape.

  Further, the present invention can adopt a configuration in which the section of the chucking portion is a circle or a polygon that is a multiple of three.

  According to the tape transfer jig according to the present invention, it is possible to greatly reduce the time and work load of the tape transfer work by effectively using a simple method and a tool that is commonly used by equipment business operators such as electric drills. There is an advantageous effect that it can be reduced.

1 is an overall view of a tape transfer jig according to the present invention. It is an enlarged view of the attachment part to the electric driver of the tape transfer jig which concerns on this invention. It is an enlarged view of the attachment part to an electric driver in case it has the positioning protrusion of the winding member which is another Example of the tape transfer jig which concerns on this invention. It is a structure explanatory view explaining the composition in case the above-mentioned winding member holding projection concerning the present invention is spiral. It is a figure explaining that the positioning protrusion of the cylindrical member which is another Example of the tape transfer jig which concerns on this invention is flange shape, and also guides a tape.

The tape transfer jig 1 according to the present invention is characterized in that the commercial tape 30 can be subdivided easily by being added to a tool used at a work site. Embodiments will be described below with reference to the drawings.
The overall shape of the tape transfer jig 1 and the shape of each part shown in the present embodiment are not limited to the embodiments described below, but are within the scope of the technical idea of the present invention, that is, the same operation. It can change within the range of the shape and dimension which can exhibit an effect.

The present invention will be described with reference to FIGS.
FIG. 1 is an overall view of a tape transfer jig 1 according to the present invention. FIG. 2 is an enlarged view of a portion where the tape transfer jig 1 according to the present invention is attached to the electric driver 13. Fig.1 (a) shows the whole side view at the time of use of this invention, FIG.1 (b) is the whole side view in tape winding. FIG. 2A is a diagram illustrating a part of the tape transfer jig 1 and the electric driver 13, and FIG. 2B is a diagram illustrating a state where the winding member 3 is inserted into the transmission member 2. FIG. 2C is a cross-sectional view showing the relationship between the transmission member 2 and the winding member 3.

The tape transfer jig 1 includes a transmission member 2 and a winding member 3. The outline of the whole will be described. The tape transfer jig 1 attaches the transmission member 2 to the chuck portion of the electric driver 13 in the same manner as a drill bit or a driver bit. Thereafter, the winding member 3 is inserted into the transmission member 2 (FIG. 1A). In this state, one end of the tape 12 to be subdivided with respect to the winding member 3 is attached and the electric driver 13 is operated, whereby the winding member 3 is rotated via the transmission member 2 and the tape 12 is rotated. 3 (FIG. 1B).

  The transmission member 2 has the winding member holding projection 4 and the winding member positioning portion 6 on the outer peripheral portion thereof, and has a thickness and a shape that can be fixed to the chuck portion of the electric driver 13. The appropriate thickness is about φ0.8 mm to φ2.5 mm. This is because if the thickness is too large, the amount of tape wound is reduced. In addition, if it is a rotary tool which can mount | wear with the transmission member 2, it will not be specifically limited to the electric screwdriver 13, It may be rotary tools, such as an impact wrench and a leuter, and either an air drive type or an electric drive type is sufficient. A driving method may be used.

  Further, a winding member holding projection 4 for transmitting the rotational force from the electric driver 13 to the winding member 3 is provided on the shaft surface of the transmission member 2, and a screw using the shape of the projection is provided. The transmission member 2 and the winding member are integrated by engagement means such as fitting or fitting.

The winding member 3 is a portion that is inserted into the transmission member 2 and serves as a shaft for subdividing the tape 12, and is hollow. The material of the winding member 3 is preferably elastic to some extent. For example, vinyl chloride and PE are suitable. As a relatively hard material, acrylic, PC and the like are suitable. When utilizing the elastic characteristics of the material, the winding member 3 may have an inner diameter of the winding member 3 that is smaller than the protruding dimension of the winding member holding projection 4, so-called fitting tolerance, or may be an interference fit. The protrusion 4 may be screwed by adopting a “spiral shape” as the protrusion shape. That is, the transmission member 2 and the winding member 3 are sufficiently brought into contact with each other so that the winding member 3 does not idle (slide) with respect to the rotation of the transmission member 2, and only when the insertion member is fixed. In addition, the connection state is such that it can be easily removed.

In addition, sectional drawing of the transmission member 2 and the winding member 3 is shown in FIG.2 (c). The transmission member 2 and the winding member 3 are evenly contacted by the winding member holding projection (spiral) 4 </ b> A that forms the outer diameter of the transmission member 2. Further, since the contact portion between the winding member 3 and the winding member holding projection (helical shape) 4A is not a surface but close to a line and has a wide interval like a courselet, the winding member 3 is connected to the transmission member. 2 can reduce the amount of resistance at the time of insertion and removal, and can be easily inserted and removed. Further, in order to smoothly wind the tape 12 around the winding member 3, it is important that the transmission member 2 and the winding member 3 do not idle.

FIG. 3 shows another embodiment of the tape transfer jig according to the present invention, which is an example in which the winding member holding projection 4 has a serrated projection, and FIG. FIG. 3 (b) shows a configuration in which a partial projection is provided, and FIG. 3 (c) shows a flange-like configuration. The case where the structure which positions by a level | step difference is employ | adopted is shown.
In such an embodiment, the tape can be divided efficiently, but the winding member holding projection (spiral shape) 4A tends to be slightly resistant when the winding member 3 is inserted into and removed from the transmission member 2. Therefore, a protrusion structure that can be easily inserted and removed is required.

Therefore, such a protrusion is a protrusion extending in the longitudinal direction, such as a winding member holding protrusion (serrated shape) 4B, so that it is less likely to become a resistance during insertion and removal. Further, by adopting the shape of the winding member holding protrusion (serration shape) 4B, the rotation is most resistant to the rotation, and the idling between the transmission member 2 and the winding member 3 is further prevented. I can do it. The shape of the winding member holding projection (serrated shape) 4B may be four as shown in FIG. 3 (a), or may be eight as shown in FIG. 3 (b). Further, as shown in FIG. 3C, slipping may be further avoided by attaching a pawl in the rotation direction.

In addition, when the commercially available tape 30 is subdivided using the present invention, the work efficiency may be lowered if the insertion position of the winding member 3 is not determined. Therefore, by arranging the winding member positioning portion 6 at a position close to the base end of the transmission member 2, the insertion position of the winding member 3 relative to the transmission member 2 is made constant. The winding member positioning part 6 has a step shape, a protruding shape, or a flange shape. In addition, even if it is not the same shape, it is good also as a positioning shape which has the same effect.

The stepped shape, the protruding shape, or the flange shape is located on the proximal side of the winding member holding projection (serration shape) 4B of the transmission member 2 and is attached to the chucking portion of the electric driver 13 in the state where the chucking portion is mounted. It is located on the tip side of the king part. However, when adopting a structure without a step in the chucking portion as shown in FIG. 4A, the abutting by the tip of the chuck mechanism of the electric driver 13 can be used as the winding member positioning portion. .

Specifically, the winding member positioning portion 6 protrudes from the diameter of the winding member 3, and the winding member 3 does not get over. Therefore, when the user inserts the winding member 3 into the transmission member 2, the user always brings the end of the winding member 3 into contact with the winding member positioning portion (positioning bump for positioning) 6. The position of the winding member 3 with respect to the transmission member 2 can be made constant (FIG. 3). In FIG. 3A, the winding member positioning portion (positioning contact step) 6 is realized by changing the thickness of the transmission member 2. Therefore, the thickness of the transmission member 2 is equal to or greater than the thickness of the winding member 3 in the winding member positioning portion (positioning bump for positioning) 6 portion.

In FIG. 3B, the winding member positioning portion (positioning contact step) 6 is a partial protrusion of the transmission member 2. This is because the winding member 3 can be prevented from climbing over the winding member positioning portion (positioning bump for positioning) 6 even if it is a partial protrusion. Further, in FIG. 3 (c), the protruding step is made into a flange shape as shown in the figure, so that the function of guiding the fingertip is exhibited, and the tape 12 is not displaced with respect to the winding member 3, Stable winding can be performed (FIG. 3C). Further, when such an aspect is adopted, the protrusion amount of the flange increases as shown in the drawings, but it is also effective to use a small flange.
Further, although not shown, a configuration in which a front end side tape guide plate for providing the same guide function on the front end side is also effective. In that case, it is desirable to have a divided structure by fitting or the like.

FIG. 4 shows an embodiment in which the winding member holding projection 4 of the tape transfer jig 1 according to the present invention has a spiral shape and the chucking portion has the same shape as a hexagonal driver bit. Yes.
FIG. 4A shows that the winding member holding projection 4A has a spiral shape, and the spiral projection is circumferentially contacted in a predetermined region from a position close to the step on the electric driver side. A ratchet part is comprised by the straight shape without a level | step difference, and has illustrated the case where the structure concerned is the simplest.

FIG. 4B shows a shape when the ratchet portion is held corresponding to the chucking function for the electric driver. Specifically, the ratchet 7 in FIG. 4B is an embodiment in the case of having a substantially hexagonal shape 7B in a cross-sectional view, and not only an electric driver but also an impact wrench, a rotation mechanism such as a leuter, and the like. It is desirable to be able to cope with any of the tools provided with. That is, the circular shape 7A shown on the left side of FIG. 4C, the triangle 7C shown on the right side of FIG. 4C, or the center of FIG. 4C, which is a multiple of 3, is shown. Hexagon 7B or the like.
Since the hexagonal shape 7B described in the center of FIG. 4C is standardized, the versatility is further enhanced by adopting a so-called bit shape having dimensions corresponding to the hexagonal shape 7B.

As for chucking for fixing the transmission member 2 and the winding member 3, the chucking portion 7 of the transmission member 2 is preferably in accordance with a shape that can be held by a chuck function of a commercially available electric screwdriver or the like. Although it is desirable to provide the described chucking shape, in order to increase the purpose of reducing the risk of slipping, a polygon is more desirable than a circle 7A in terms of holding force.
Since most commercially available chucks are generally composed of three claws, the minimum number of faces is the triangle 7C, and it is considered that the holding power is reduced in the nine-sided shape. Hexagon 7B is most desirable.

A winding procedure will be described. First, the transmission member 2 is fixed to the electric driver 13. Next, the winding member 3 is inserted into the transmission member 2. Note that this order may be reversed. At this time, when the protrusion provided on the outer periphery of the transmission member 2 is a winding member holding protrusion (spiral) 4A, the winding member 3 is mounted by screwing while rotating the winding member 3. Thereafter, the operation of the electric driver 13 is started while lightly pressing the end of the tape 12 against the outer peripheral surface of the winding member 3, and the tape 12 is wound around the winding member 3.

    FIG. 5 is an explanatory diagram of a use state of the tape transfer jig according to the present invention, FIG. 5 (a) shows a cross-sectional shape in a top view, and FIG. 5 (b) is a winding jig according to the present invention. It is a perspective view which shows the construction state using this. As shown in FIG. 5 (a), when winding an insulating tape or a protective tape directly on a normal pipe or wire, and after winding the heat insulating material 22 shown in the left half of FIG. 5 (a), Furthermore, the periphery may be wound with the same tape, and the distances between the gap A, the gap B, the gap C, and the gap D are problematic. Further, the gap A is a distance between the adjacent pipes 21 and 21, the gap B is a distance between objects wrapped with a heat insulating material, and the gap C is a distance between the pipe and the wall. D indicates the distance between the heat insulating material and the wall.

  When the commercially available tape 30 is used, it cannot pass through any of the gaps A, B, C, and D. However, a tape TA (40) after winding, a tape TB (41) after winding, and a tape TB (41) after winding are obtained by winding the tape 12 wound from the tape 30 around the winding member 3 using the tape transfer jig according to the present application. The tape TC (42) after winding is obtained. The tape TA (40) shows a state where the diameter of the winding member 3 and the outer diameter of the tape can be minimized, and the tape TB (41) is a gap D (gap between the heat insulating material and the pipe) 27. It shows the state of transfer as a tape of a size that can be passed through. The tape TC (42) is sized to pass through the gap D (27), and illustrates a case where a configuration in which the winding member 3 is made as small as possible and the winding amount of the tape 12 is secured to the maximum is adopted. ing. Thus, if it is the external shape which can enter each each clearance gap, the diameter of a winding member does not influence.

FIG.5 (b) illustrates the case where the piping 21 of the hot water supply equipment 20 grade | etc., Is heat-retained using the tape transfer jig 1 based on this invention. Although the facility 20 shows the Example using the hot water supply equipment 20 in the figure, the equipment 20 is not limited to the hot water supply equipment, and air conditioning equipment such as an air conditioner, electricity, gas, water supply, etc. It is a technology that can be applied to piping equipment construction in general. As shown in FIG. 5B, in the case of the facility 20 in which a plurality of pipes are densely arranged, the gap A24 to the gap D27 change depending on the presence or absence of the abandonment material and the winding amount of the tape. According to the tape transfer jig, it is possible to cope with a wide range of working conditions by using a winding amount corresponding to the change in the gap.

  It is understood that the tape transfer jig according to the present invention has great industrial applicability in terms of improving the efficiency of tape subdivision work by adding a necessary amount of tape to an electric driver in advance.

DESCRIPTION OF SYMBOLS 1 Tape transfer jig 2 Transmission member 3 Winding member 4 Winding member holding protrusion 4A Winding member holding protrusion (spiral)
4B Winding member holding projection (serrated)
6 Winding member positioning part 6A Winding member positioning part (protruding shape against butting for positioning)
6B Winding member positioning part (positioning and guide shape)
7 Chucking part 7A Chucking part (circle)
7B Chucking part (hexagon)
7C Chucking part (triangle)
12 Tape 13 Electric Driver 20 Equipment 21 Piping 22 Heat Insulating Material 23 Wall 24 Gap A (Gap Between Pipes)
25 Crevice B (Gap between heat insulation outer peripheral parts)
26 Clearance C (Gap between pipe and wall)
27 Gap D (gap between the insulation and the wall)
30 Commercially available tape 40 Tape TA after winding
41 Tape TB after winding
42 Tape TC after winding

Claims (5)

A transmission member for transmitting a rotational force from the electric driver, and a winding member for winding the tape through the transmission member,
The transmission member is constituted by the chucking unit for obtaining a rotational force from the electric driver and winding member holding projection and the winding member positioning unit,
The winding member has a through hole into which the transmission member is inserted,
The through hole is fitted to the transmission member by fitting with the winding member holding projection, and transmits the rotational force from the electric driver to the winding member via the chucking portion. A tape transfer jig , wherein the tape is wound from a large-diameter winding member to a small-diameter winding member by winding the tape around the tape.   The tape winding jig according to claim 1, wherein the winding member holding protrusion has a spiral shape.   The tape winding jig according to claim 1, wherein the winding member holding projection is a projection extending in a longitudinal direction.   The tape winding jig according to any one of claims 1 to 3, wherein the winding member positioning portion is any one of a step shape, a protruding shape, and a flange shape. The tape transfer jig according to any one of claims 1 to 4, wherein a cross section of the chucking portion is a circle or a polygon that is a multiple of three.